Pharmacokinetics of an etoposide infused over three days: concomitant infusion with cisplatin.

The pharmacokinetics of a 72-hour infusion of 240 mg/m2 etoposide administered concurrently with 90 mg/m2 cisplatin was studied in 12 lung cancer patients. The area under the curve (AUC), elimination half-life, steady state concentration, systemic clearance, renal clearance of etoposide and distribution volume at steady state were 225.4 +/- 39.2 micrograms x h/ml, 8.1 +/- 3.4 h, 3.1 +/- 0.6 micrograms/ml, 18.8 +/- 3.1 ml/min/m2, 3.1 +/- 1.4 ml/min/m2, 9.6 +/- 3.8 l/m2, respectively, which were in accordance with those reported previously in patients treated with etoposide alone. Although concentration at 24 hours, total bilirubin level and total protein level were correlated with the AUC which in turn correlated with hematologic toxicity, the variables were not predictive of hematologic toxicity. We conclude that the concomitant administration of cisplatin at a dose level of 30 mg/m2/day might not affect the pharmacokinetics of prolonged etoposide infusion.     

Pharmacokinetic analysis of carboplatin in patients with cancer who are undergoing hemodialysis

Purpose

To examine the safety of carboplatin-based chemotherapy and the applicability of the Calvert formula in patients with cancer who are undergoing hemodialysis.

Methods

We treated two patients who were undergoing hemodialysis and received carboplatin-based chemotherapy to treat non-small-cell lung cancer or ovarian cancer. The dose of carboplatin was calculated by the Calvert formula. Glomerular filtration rate was considered to be 0, and the target area under the plasma concentration versus time curve (AUC) was 4 (carboplatin dose, 100 mg) for patient 1 and 5 (125 mg) for patient 2. Carboplatin was administered as a 1-h intravenous infusion on day 1. Hemodialysis was performed for 3 or 4 h, starting 24 h after the infusion of carboplatin had begun. Heparinized blood samples were collected during the first cycle of chemotherapy.

Results

The AUCs in patients 1 and 2 were 4.7 and 6.1 (mg/ml min), which were about 20% higher than the target values (4 and 5 mg/ml min, respectively). In the absence of hemodialysis, the hypothetical AUCs were 6.2 and 7.6 (mg/ml min), respectively. The pre-dialysis body clearances of carboplatin were 16.1 and 16.5 ml/min, with elimination half-lives of 17.5 and 13.8 h, respectively.

Conclusion

By performing hemodialysis 24 h after the start of chemotherapy, we obtained reproducible and robust AUC data. Use of the Calvert formula allowed carboplatin-based chemotherapy to be performed safely. Our results suggest that the non-renal clearance of carboplatin is lower in Japanese patients than in non-Asian patients.     

Pharmacokinetics and pharmacodynamics of prolonged oral etoposide in women with metastatic breast cancer

The pharmacokinetics and pharmacodynamics of prolonged oral etoposide chemotherapy were investigated in 15 women with metastatic breast cancer who received oral etoposide 100 mg as a single daily dose for up to 15 days. There was considerable interpatient variability in the day 1 pharmacokinetic parameters: area under the plasma concentration time curve (AUC) (0–24 h) 1.95±0.87 mg/ml per min (mean ± SD), apparent oral clearance 60.9±21.7 ml/min per 1.73 m², peak plasma concentration 5.6±2.5 g/ml, time to peak concentration 73±35 min and half-life 220±83 min. However, intrapatient variability in systemic exposure to etoposide was much less with repeated doses. The intrapatient coefficient of variation (CV) of AUC for day 8 relative to day 1 was 20% and for day 15 relative to day 1 was 15%, compared to the day 1 interpatient CV of 45%. Neutropenia was the principal toxicity. Day 1 pharmacokinetic parameters were related to the percentage decrease in absolute neutrophil count using the sigmoidal E_max equation. A good fit was found between day 1 AUC and neutrophil toxicity (R ²=0.77). All patients who had a day 1 AUC>2.0 mg/ml per min had WHO grade III or IV neutropenia. The predictive performance of the models for neutrophil toxicity was better for AUC (percentage mean predictive error 5%, percentage root mean square error 18.1%) than apparent oral clearance, peak plasma concentration, or daily dose (mg/m²). A limited sampling strategy was developed to predict AUC using a linear regression model incorporating a patient effect. Data sets were divided into training and test sets. The AUC could be estimated using a model utilizing plasma etoposide concentration at only two time points, 4 h and 6 h after oral dosing (R ²=98.9%). The equation AUC_pr=–0.376+0.631×C_4h+0.336×C_6h was validated on the test set with a relative mean predictive error of –0.88% and relative root mean square error of 6.4%. These results suggest monitoring of AUC to predict subsequent myelosuppression as a strategy for future trials with oral etoposide.Division of Haematology and Medical Oncology, Peter MacCallum Cancer Institute, Locked Bag 1, A'Beckett St, Melbourne 3000, Australia     

Etoposide pharmacokinetics in patients with normal and abnormal organ function

Precise guidelines for dose modification of etoposide in patients with hepatic dysfunction have not been determined. Etoposide pharmacokinetics were determined in 17 patients. Nine patients had bilirubin less than or equal to 1 mg/dL and eight had bilirubin ranging from 1.9 to 23 mg/dL. Twelve patients received etoposide 100 mg/m2 days 1, 3, and 5, in combination with cisplatin 70 mg/m2 or iproplatin 225 mg/m2 on day 1. Five patients received only one dose of etoposide. Etoposide was measured using a published high pressure liquid chromatography (HPLC) method which also quantitates picro etoposide and its hydroxy acid. Systemic clearance, Vdss and t1/2 beta averaged (+/- SD) 21.4 (+/- 7.4) mL/min/m2, 10.7 (+/- 4.1) L/m2, and 8.1 (+/- 2.8) hours in the nine patients with bilirubin less than or equal to 1 mg/dL, and 22.4 (+/- 9.6) mL/min/m2, 13.6 (+/- 11.3) L/m2, and 8.4 (+/- 3.9) hours in the eight patients with bilirubin 1.9 to 23.0 mg/dL. Stepwise multiple linear regression analysis of liver and renal function tests and other patient-specific variables identified creatinine clearance as the strongest predictor of etoposide systemic clearance (r2 = 40.8). Serum albumin was identified as the next strongest predictor, improving the r2 to 57.3%. Cumulative biliary excretion of unchanged etoposide and glucuronide or sulfate conjugates over 48 hours accounted for less than 3% of the dose in six patients studied. Toxicity occurred in patients with normal and abnormal bilirubin and was unrelated to etoposide clearance. Patients with total bilirubin 1.9 to 23 mg/dL, but creatinine clearance greater than 30 mL/min/m2 had etoposide clearance within the range for patients with normal liver function (16.8 to 35 mL/min/m2). Although these patients did not have reduced etoposide clearance, the major routes of etoposide non-renal elimination remain to be clearly defined. Additional patients should be evaluated to establish more precise guidelines for dosing etoposide in patients with abnormal liver function.     

Pharmacokinetics of Carboplatin in a patient with both testicular cancer and hemodialysis-requiring kidney failure

We report on a patient with advanced seminoma successfully treated with 4 cycles of carboplatin (80-100 mg/m2 per cycle) and etoposide (240-300 mg/m2) while being on hemodialysis 3 times weekly. Hemodialysis was performed on day 2 and day 3 of each chemotherapy cycle. Plasma platinum levels were determined at regular intervals at days 1, 2 and 3 of each cycle. The drug doses for cycle 2-4 were reduced due to grade 4 hematological toxicity during the preceding cycle. In spite of these drug reductions the AUC between 0-51 h remained unchanged for all cycles. Platinum was found in the plasma collected on day 1 of cycle 2-4 prior to start of the scheduled carboplatin infusion. The demonstrated pharmacokinetics of carboplatin (and probably also of etoposide) should be considered during chemotherapy of a testicular cancer patient on hemodialysis.     

Phase I and pharmacokinetic study of brequinar sodium (NSC 368390)

Brequinar sodium is a quinoline carboxylic acid derivative that has shown antitumor activity in a number of in vivo murine and human tumor xenograft models. Its mechanism of action is blockade of de novo pyrimidine biosynthesis by inhibition of dihydroorotic acid dehydrogenase. In vitro and in vivo studies demonstrate the superiority of prolonged drug exposure in achieving tumor growth inhibition. This phase I study evaluated the administration of brequinar sodium by short, daily i.v. infusion for 5 days repeated every 4 weeks. Fifty-four subjects were enrolled in the study and received drug in doses ranging from 36-300 mg/m2. The dose-limiting toxicities were mucositis and diffuse skin rash. Other toxicities included myelosuppression, nausea, vomiting, malaise, and burning at the infusion site. The maximum tolerated dose on the "daily times 5" schedule was 300 mg/m2. The recommended phase II dose is 250 mg/m2. Pharmacokinetic analysis of the day 1 drug clearance curves in 51 subjects showed slight nonlinearity in the relationship between dose and area under the clearance curve (AUC). The dose versus AUC relationship was well described using a Michaelis-Menten model of brequinar elimination kinetics with Vmax = 45 (micrograms/ml)/h and Km = 123 micrograms. Analysis of the day 5 drug clearance curves revealed a diminution in Vmax to 30 (micrograms/ml)/h. As a consequence of the reduction in Vmax brequinar plasma concentrations on day 5 were higher than predicted from day 1 drug kinetics. Pharmacodynamic analysis of the day 1 kinetic parameters and the toxicities occurring during the first cycle of drug therapy revealed significant correlations between mucositis and dose, AUC, and peak brequinar concentration; between leukopenia and AUC and peak drug concentration; and between thrombocytopenia and beta elimination rate.     

Plasma etoposide catechol increases in pediatric patients undergoing multiple-day chemotherapy with etoposide.

PURPOSE: The purpose of this research was to determine inter- and intrapatient differences in the pharmacokinetic profiles of etoposide and its genotoxic catechol metabolite during conventional multiple-day dosing of etoposide in pediatric patients. EXPERIMENTAL DESIGN: Seven pediatric patients with various malignancies received etoposide at a dose of 100 mg/m(2) i.v. over 1 h daily for 5 days. Blood samples were taken at selected time points on days 1 and 5. Plasma and protein-free plasma concentrations of etoposide and etoposide catechol were determined using a validated liquid chromatography/tandem mass spectrometry assay. Pharmacokinetic parameters of both etoposide and etoposide catechol were calculated using the WinSAAM modeling program developed at NIH. RESULTS: The mean maximum concentration (C(max)) for total (0.262 +/- 0.107 micro g/ml) and free catechol (0.0186 +/- 0.0082 micro g/ml) on day 5 were higher than the mean C(max) for total (0.114 +/- 0.028 micro g/ml) and free catechol (0.0120 +/- 0.0091 micro g/ml) on day 1. The mean area under the plasma concentration-time curve (AUC)(24h) for total (105.4 +/- 49.1 micro g.min/ml) and free catechol (4.89 +/- 2.23 micro g x min/ml) on day 5 were much greater (P < 0.05) than those for total (55.9 +/- 16.1 micro g x min/ml) and free catechol (3.04 +/- 1.04 micro g x min/ml) on day 1. In contrast, the AUC(24h) for etoposide was slightly lower on day 5 than on day 1. CONCLUSIONS: The C(max) and AUC(24h) for etoposide catechol were significantly higher on day 5 than on day 1. This suggests that metabolism of etoposide to its catechol metabolite increases in pediatric patients receiving multiple-day bolus etoposide infusions. These findings may be relevant to future reduction of the risk of leukemia as a treatment complication, because etoposide and etoposide catechol are both genotoxins.     

Pharmacokinetics of very high-dose oral melphalan in cancer patients

The pharmacokinetics and systemic availability of melphalan after high-dose oral administration with and without 1,3-bis(2-Chloroethyl)-1-nitrosourea (BCNU) or etoposide were examined in three patients undergoing autologous bone marrow transplantation. Patient 1 (advanced melanoma) received melphalan at 80 mg/m2/day p.o. on days -6, -5, and -4, followed by BCNU at 300 mg/m2/day i.v. on days -3, -2, and -1 prior to bone marrow transplantation. Patient 2 (advanced colon carcinoma) received melphalan at 75 mg/m2/day p.o. on days -3, -2, and -1. Patient 3 (advanced refractory lymphoma) received etoposide at 800 mg/m2/day i.v. on days -7, -5, and -3, followed by melphalan at 157 mg/m2/day p.o. on days -2 and -1. Melphalan was administered as a bolus oral dose, using 2-mg tablets. Blood samples were collected at 0, 5, 10, 15, 30, and 45 min and 1, 2, 3, 4, 6, 8, 12, and 24 h after each dose of melphalan. Peak plasma melphalan concentrations in the three patients ranged from 0.354 (patient 2) to 1.768 micrograms/ml (patient 1). Plasma melphalan concentration X time products (C x Ts) showed extreme variability in one patient (patient 2), ranging from 0.76 to 4.48 micrograms.h/ml. To determine the relative systemic availability of orally administered melphalan, i.v. C X Ts proportional to the p.o. doses were extrapolated from previously reported i.v. bolus pharmacokinetic data. The p.o.:i.v. plasma C X T ratios for high-dose melphalan ranged between 0.09 (patient 3) and 0.58 (patient 2). Although these C X T data suggest a dose-response for orally administered melphalan, the systemic availability of these high p.o. melphalan doses was extremely variable, both within and between study patients. Thus, we cannot recommend the use of high-dose p.o. melphalan regimens in patients undergoing autologous bone marrow transplantation.     

Limited sampling models for amonafide (NSC 308847) pharmacokinetics

The limited sampling model (LSM) offers a means of estimating the area under the concentration-time curve (AUC) from only two timed plasma concentrations. In this study, pharmacokinetic profiles were simulated for 23 patients treated with amonafide, using each patient's individual pharmacokinetic parameters. Data were simulated for a dose of 250 mg/m2 administered over 1 h. The initial 15 patients formed the training data set. Based on the training data set, five different LSMs were generated, with the multiple r ranging from 0.92 to 0.98. A single model was selected as optimal: AUC (micrograms min/ml) = 292.9 (min) C45 (micrograms/ml) + 3262 (min) C1440 (micrograms/ml) + 21.8 (micrograms min/ml) dose (mg/m2)/250 mg/m2 where C45 = 45-min plasma concentration and C1440 = 24-h plasma concentration. This model was revalidated on a second test data set of seven patients actually treated with a 1-h infusion. The relative root mean square predictive error was 15.8%, acceptable for most clinical uses. We conclude that the LSM is a powerful tool for estimation of the AUC in a large patient population. The LSM may facilitate population pharmacodynamic studies in conjunction with Phase II trials.     

Pharmacokinetics of paclitaxel and carboplatin in a hemodialysis patient with metastatic urothelial carcinoma--a case report

A 69-year-old-man undergoing hemodialysis for 8 years developed metastatic urothelial carcinoma and received combination chemotherapy with paclitaxel and carboplatin. Paclitaxel 175 mg/m2 was given as a 3-hour intravenous infusion, and carboplatin was dosed to the area under the plasma concentration-time curve (AUC) of 5 mg.min/ml calculated according to the Calvert formula as a 30-minute intravenous infusion immediately after paclitaxel. Hemodialysis was started 1 hour after carboplatin, then their pharmacokinetics was determined in the patient. The AUC of paclitaxel and carboplatin were 15.2 and 64.56 micrograms.h/ml, respectively. The metastatic tumor size was reduced by more than 20% after 3 courses of this chemotherapy. Grade 3 neutropenia and grade 1 thrombopenia were observed. This is the first report that the combination of paclitaxel and carboplatin is feasible in a patient with metastatic urothelial carcinoma undergoing hemodialysis, with low toxicity and safety.     

A study of the feasibility and accuracy of pharmacokinetically guided etoposide dosing in children.

Pharmacokinetically guided dosing was performed in nine paediatric patients receiving etoposide. Doses on day 2 of a 2- or 3-day schedule were adapted on the basis of the day-1 area under the plasma etoposide concentration vs time curve (AUC). The day-1 AUC was estimated using a limited sampling model and the day-2 target AUC defined by the etoposide dose-AUC relationship observed in 33 children. Target AUC values (4.6-8.2 mg ml(-1) x min) were achieved with a high degree of precision and with little bias (mean error 11% and root mean squared error 15% respectively). Pharmacokinetic parameters were similar to those reported previously in children, although interpatient pharmacokinetic variability was less than that observed previously: plasma clearance, 23 (18-26) ml min(-1) m(-2); volume of distribution at steady state (Vdss), 6.0 (3.9-8.9) l m(-2); t(1/2) 254 (127-550) min (median and range). This study has demonstrated that pharmacokinetically guided dosing with etoposide is feasible. However, pharmacokinetically guided dosing is likely to be of most benefit in patients with abnormalities of renal or hepatic function, or in children with prior exposure to cisplatin.     

Pilot phase II trial of high-dose etoposide combined with cisplatin in the treatment of refractory lung cancer]

The efficacy of combined high-dose etoposide with standard dose cisplatin was evaluated in patients who had refractory lung cancer after standard chemotherapy. Each patient was given etoposide at 500 mg/m2/day on day 1 to 3 continuously (total dose 1,500 mg/m2) and cisplatin at 80 mg/m2 on day 1. Fifteen patients (7 adenocarcinoma, 5 small cell lung cancer, 2 squamous cell lung cancer and 1 sarcoma, which latter was difficult to distinguish from giant cell carcinoma) were entered in this study. The overall response was 41.7% (5 of 12); five partial response, 6 no change, and 1 progressive disease. Three treatment-related deaths were observed; one resulted from sepsis and two from respiratory failure because of tumor progression. All of the patients developed severe myelosuppression; the mean nadir white blood cell count was 400, and the mean nadir platelet count was 24,000 in 28 evaluable courses. The range of maximum concentration of etoposide determined by HPLC was from 17.4 to 39.1 micrograms/ml. These results suggest that high-dose etoposide combined with a standard dose of cisplatin is effective against refractory lung cancer.     

A phase I and pharmacokinetic study of weekly paclitaxel and carboplatin in patients with metastatic esophageal cancer.

PURPOSE: To determine the maximum-tolerated dose, toxicity profile, and pharmacokinetics of a fixed dose of paclitaxel followed by increasing doses of carboplatin, given weekly to patients with advanced esophageal or gastric junction cancer. EXPERIMENTAL DESIGN: Paclitaxel was administered on day 1 as a 1-h infusion at a fixed dose of 100 mg/m(2) followed by a 1-h infusion of carboplatin targeting an area under the curve (AUC) of 2-5 mg x min/ml, with cycles repeated on days 8, 15, 29, 36, and 43. RESULTS: Forty patients [36 males; median (range) age, 57 (40-74) years] were enrolled. Dose-limiting toxicity was observed at a carboplatin AUC of 5 mg x min/ml and consisted of treatment delay attributable to myelosuppression. No grade 3/4 treatment-related nonhematological toxicity was observed. The highest dose intensity (>95% of the planned dose over time) was achieved with a carboplatin AUC of 4 mg x min/ml. The mean (+/-SD) AUCs of unbound (Cu) and total paclitaxel were 0.662 +/- 0.186 and 7.37 +/- 1.33 micro M x h, respectively. Clearance of Cu was 188 +/- 44.6 liter/h/m(2), which is not significantly different from historical data (P = 0.52). Cremophor EL clearance was 123 +/- 23 ml/h/m(2), similar to previous findings. Of 37 patients evaluable for response, 1 had complete response, 19 had partial response, and 10 had stable disease, accounting for an overall response rate of 54%. CONCLUSIONS: This regimen is very tolerable and effective, and the recommended doses for additional studies are paclitaxel (100 mg/m(2)), with carboplatin targeting an AUC of 4 mg x min/ml.     

Carboplatin and etoposide pharmacokinetics in patients with testicular teratoma

Summary The pharmacokinetics of carboplatin and etoposide were studied in four testicular teratoma patients receiving four courses each of combination chemotherapy consisting of etoposide (120 mg/m² daily×3), bleomycin (30 mg weekly) and carboplatin. The carboplatin dose was calculated so as to achieve a constant area under the plasma concentration vs time curve (AUC) of 4.5 mg carboplatin/ml x min by using the formula: dose=4.5×(GFR+25), where GFR is the absolute glomerular filtration rate measured by ⁵¹Cr-EDTA clearance. Carboplatin was given on either day 1 or day 2 of each course and pharmacokinetic studies were carried out in each patient on two courses. Etoposide pharmacokinetics were also studied on two separate courses in each patient on the day on which carboplatin was given and on a day when etoposide was given alone. The pharmacokinetics of carboplatin were the same on both the first and second courses, on which studies were carried out with overall mean ± SD values (n=8) of 4.8±0.6 mg/ml x min, 94±21 min, 129±21 min, 20.1±5.41, 155±33 ml/min and 102±24 ml/min for the AUC, beta-phase half-life (t_1/2), mean residence time (MRT), volume of distribution (Vd) and total body (TCLR) and renal clearances (RCLR), respectively. The renal clearance of carboplatin was not significantly different from the GFR (132±32 ml/min). Etoposide pharmacokinetics were also the same on the two courses studied, with overall mean values ±SD (n=8) of: AUC=5.1±0.9 mg/ml x min, t_1/2=40±9 min, t_1/2=257±21 min, MRT=292±25 min, Vd=13.3±1.31, TCLR=46±9 ml/min and RCLR=17.6±6.3 ml/min when the drug was given alone and AUC=5.3±0.6 mg/ml x min, t_1/2=34±6 min, t_1/2=242±25 min, MRT=292±25 min, Vd=12.5±1.81, TCLR=43±6 ml/min and RCLR=13.4±3.5 ml/min when it was given in combination with carboplatin. Thus, the equation used to determine the carboplatin accurately predicted the AUC observed and the pharmacokinetics of etoposide were not altered by concurrent carboplatin administration. The therapeutic efficacy and toxicity of the carboplatin-etoposidebleomycin combination will be compared to those of cisplatin, etoposide and bleomycin in a randomised trial.     

Phase I clinical and pharmacological study of 72-hour continuous infusion of etoposide in patients with advanced cancer

Etoposide (VP-16) is a semisynthetic epipodophyllotoxin that exhibits cell cycle phase specific cytotoxicity and enhanced effectiveness with increasing duration of drug exposure. We have therefore conducted a Phase I trial to determine the side effects, tolerable doses, and pharmacokinetic parameters of VP-16 given by continuous i.v. infusion to patients with advanced cancer. Eighteen patients were treated with varying dosages of VP-16 infused continuously for 72 consecutive hours every 28 days. Using this schedule, the maximally tolerated dosage of VP-16 was 150 mg/m2/day for patients with good performance status and 125 mg/m2/day for more debilitated cancer patients. Hematological toxicity was dose limiting with median granulocyte and platelet nadirs of 700/mm3 and 116,000/mm3, respectively, at a dose of 150 mg/m2/day. Other toxicities included only mild nausea, vomiting, and alopecia. Plasma and urine VP-16 concentrations were determined using a high-performance liquid chromatography assay. At a VP-16 dosage of 150 mg/m2/day, steady-state VP-16 concentrations were in the range of 2.1 to 7.0 micrograms/ml in all patients. Further pharmacokinetic analysis revealed that the plasma clearance of VP-16 was consistently near 25 ml/min/m2 (independent of dosage) and that renal clearance accounted for only 15% of VP-16 total plasma clearance. Patient age was found to be the most important factor correlating with plasma clearance of VP-16. Linear regression analysis also revealed that both the plasma VP-16 concentration at steady state and the concentration of VP-16 in plasma at 24 h from the start of the infusion correlated with hematological toxicity; no other patient characteristics correlated with hematological toxicity. The recommended VP-16 dose for Phase II trials of 72-h continuous infusion VP-16 is 150 mg/m2/day in patients with good performance status.     

Biliary excretion of etoposide in children with cancer

Purpose: Two children with soft tissue sarcomas receiving etoposide as part of their standard clinical treatment had external biliary drainage due to obstruction of the bile duct. These unusual cases provided an opportunity to investigate the biliary clearance of etoposide by determining etoposide concentrations in bile and plasma samples obtained during chemotherapy. Patients and methods: Etoposide was administered to patient 1 at a dose of 150 mg/m², as a 4 h infusion, on each of three days of treatment. Patient 2 received a daily etoposide dose of 800 mg/m² as a 24 h continuous infusion, also over a 3-day treatment period. Bile and plasma samples were obtained at regular intervals from both patients and etoposide levels quantified by LC/MS analysis. Results and discussion: Biliary etoposide clearance was approximately equal to the flow of bile, with an average clearance of 0.32 ml/min determined in patient 1. Less than 2% of the etoposide dose administered was excreted in the bile in either patient studied, indicating that biliary clearance of etoposide is relatively minor. These results suggest that etoposide dose adjustment is unnecessary in patients with biliary obstruction.     

Pharmacokinetic evaluation of high-dose etoposide phosphate after a 2-hour infusion in patients with solid tumors

 Etoposide phosphate, a water soluble prodrug of etoposide, was evaluated at levels potentially useful in transplantation settings in patients with malignancies. For pharmacokinetic studies of etoposide phosphate in this phase I study, 21 patients with solid tumors were treated with etoposide phosphate given as etoposide equivalents of 250, 500, 750, 1000 and 1200 mg/m² infused over 2 h on days 1 and 2, and G-CSF 5 μg/kg per day starting on day 3 until WBC was ≥10 000/μl. Qualitative, quantitative, and pharmacokinetic analysis was performed as reported previously. Rapid conversion of etoposide phosphate into etoposide by dephosphorylation occurred at all dosage levels without indication of saturation of phosphatases. Plasma levels (C_pmax) and area under the curve (AUC) of etoposide phosphate and etoposide demonstrated linear dose effects. For etoposide, plasma disposition demonstrated biphasic clearance, with mean T_1/2α of 2.09±0.61 h, and T_1/2β of 5.83±1.71 h. An AUC as high as 1768.50 μg.h/ml was observed at a dose of 1200 mg/m². The total body clearance (TBC) showed an overall mean of 15.72±4.25 ml/min per m², and mean volume of distribution (V_Dss) of 5.64±1.06 l/m². The mean residual time (MRT) for etoposide was 6.24±1.61 h. In urine, etoposide but not etoposide phosphate, was identified with large quantitative variations (1.83% to 33.45% of injected etoposide equivalents). These results indicate that etoposide phosphate is converted into etoposide with the linear dose-related C_pmax and AUCs necessary for use of this agent at the high dosage levels needed in transplantation protocols. A comparison of pharmacokinetic parameters of high- dose etoposide with the values observed in our study with etoposide phosphate revealed comparable values for the clinically important C_pmax and AUCs, clearance, terminal T_1/2 and MRT. In contrast to the use of etoposide, etoposide phosphate can be delivered in aqueous vehicles and therefore may offer the advantage of ease of administration. Received: 18 July 1995/Accepted: 20 October 1995     

A phase I study of nolatrexed dihydrochloride in children with advanced cancer. A United Kingdom Children's Cancer Study Group Investigation

A phase I study of nolatrexed, administered as a continuous 5 day intravenous infusion every 28 days, has been undertaken for children with advanced malignancy. 16 patients were treated at 3 dose levels; 420, 640 and 768 mg/m(2)24 h(-1). 8 patients were evaluable for toxicity. In the 6 patients treated at 768 mg/m(2)24 h(-1), dose-limiting oral mucositis and myelosuppression were observed. Plasma nolatrexed concentrations and systemic exposure, measured in 14 patients, were dose related, with mean AUC values of 36 mg(-1)ml(-1)min(-1), 50 mg ml(-1)min(-1)and 80 mg ml(-1)min(-1)at the 3 dose levels studied. Whereas no toxicity was encountered if the nolatrexed AUC was <45 mg ml(-1)min(-1), Grade 3 or 4 toxicity was observed with AUC values of >60 mg ml(-1)min(-1). Elevated plasma deoxyuridine levels, measured as a surrogate marker of thymidylate synthase inhibition, were seen at all of the dose levels studied. One patient with a spinal primitive neuroectodermal tumour had stable disease for 11 cycles of therapy, and in two patients with acute lymphoblastic leukaemia a short-lived 50% reduction in peripheral lymphoblast counts was observed. Nolatrexed can be safely administered to children with cancer, and there is evidence of therapeutic activity as well as antiproliferative toxicity. Phase II studies of nolatrexed in children at the maximum tolerated dose of 640 mg/m(2)24 h(-1)are warranted.     

Phase I and pharmacokinetic study of arabinofuranosyl-5-azacytosine (fazarabine, NSC 281272).

A Phase I clinical trial of 1-beta-D-arabinofuranosyl-5-azacytosine (ara-AC or fazarabine) given as a 72-h continuous infusion on a 21-day cycle was conducted in 27 adult patients with refractory cancer. The major toxicity was reversible granulocytopenia and thrombocytopenia. Dose-limiting toxicity was observed at a dose rate of 1.96 mg/m2/h in which Grade IV leukopenia (WBC less than 1,000/mm3) occurred in 4 of 11 patients and Grade IV thrombocytopenia (platelets less than 25,000/mm3) occurred in 3 of 11 patients. Plasma steady-state levels ranged from 0.13 to 0.6 microM for doses of 1.25 to 5.94 mg/m2/h. Mean total body clearance was 647 ml/min/m2. Minor clinical responses were seen in one patient with testicular cancer, one patient with colon cancer, one patient with breast cancer, and one patient with acute nonlymphocytic leukemia. Another patient with adenocarcinoma of unknown primary had stable disease during 13 cycles of therapy. Based on the results of this study, the recommended dose for Phase II studies of 1-beta-D-arabinofuranosyl-5-azacytosine administered as a 72-h continuous infusion is 2.0 mg/m2/h (48 mg/m2/day).     

Phase I study and pharmacological analysis of cis-diammine(glycolato)platinum (254-S; NSC 375101D) administered by 5-day continuous intravenous infusion

A phase I study of cis-diammine(glycolato)platinum (254-S; NSC 375101D) was conducted in 15 patients with refractory or relapsing malignancy by 5-day continuous i.v. infusion. Three to 5 patients per dose were given 50, 75, 87.5, or 100 mg/m2/120 h (10-20 mg/m2 daily for 5 days). Toxicity evaluation and pharmacokinetic analysis were performed in 15 and 14 patients, respectively. Thrombocytopenia and neutropenia were the dose-limiting toxicities at the maximum tolerated dose of 87.5 mg/m2/120 h (17.5 mg/m2/day); however, nonhematological toxicities including renal toxicity, nausea and vomiting, and peripheral neuropathy were mild and well tolerated. The nadir of platelets and neutrophils was observed 4 and 5 weeks, respectively, after the initiation of drug infusion. Plasma and urine samples were obtained during and after infusion for quantification by atomic absorption spectrophotometry of total and free platinum levels derived from 254-S. The maximum level of total platinum was obtained after 120 h of infusion, whereas the steady state concentration of free platinum in the patients given 75 mg/m2 or more was over 0.1 microgram/ml. Free platinum levels declined monophasically, with half-lives of 0.65-2.56 h/100 mg/m2 dose. The mean area under the concentration versus time curve (AUC) in the patients treated with 75 mg/m2 was 1069 micrograms/ml, which was similar to that obtained in the patients receiving 100 mg/m2 of 254-S by i.v. drip infusion over 30 min. There was a direct correlation between the dose administered and the AUC of platinum (R = 0.757, P = 0.002) or the steady state plasma concentration of free platinum (R = 0.763, P = 0.002). The percentage of platinum excreted in urine 144 h after the initiation of infusion ranged from 73.1 to 100% for each dose level. No significant relationship was established between creatinine clearance in patients before treatment and the AUC or steady state concentration of free platinum. The plasma platinum AUC showed a linear correlation with the percentage of change in leukocytes [formula: see text] (R = 0.736, P = 0.003). In conclusion, the recommended phase II dose for a continuous infusion of 254-S is 75.5 mg/m2/120 h every 6 hours.